Phylogenetic analysis of mitochondrial genome sequences indicates that the cattle tick, Rhipicephalus (Boophilus) microplus, contains a cryptic species.

Cattle ticks of the subgenus Rhipicephalus (Boophilus) are major agricultural pests worldwide, causing billions of dollars in losses annually. Rhipicephalus (Boophilus) annulatus and R. microplus are the most well-known and widespread species, and a third species, R. australis, was recently reinstated for 'R. microplus' from Australia and parts of Southeast Asia. We use mitochondrial genome sequences to address the phylogenetic relationships among the species of the subgenus Boophilus. We sequenced the complete or partial mitochondrial genomes of R. annulatus, R. australis, R. kohlsi, R. geigyi, and of three geographically disparate specimens of R. microplus from Brazil, Cambodia and China. Phylogenetic analyses of mitochondrial genomes, as well as cox1 and 16S rRNA sequences, reveals a species complex of R. annulatus, R. australis, and two clades of R. microplus, which we call the R. microplus complex. We show that cattle ticks morphologically identified as R. microplus from Southern China and Northern India (R. microplus clade B) are more closely related to R. annulatus than other specimens of R. microplus s.s. from Asia, South America and Africa (R. microplus clade A). Our analysis suggests that ticks reported as R. microplus from Southern China and Northern India are a cryptic species. This highlights the need for further molecular, morphological and crossbreeding studies of the R. microplus complex, with emphasis on specimens from China and India. We found that cox1 and, to a lesser extent, 16S rRNA were far more successful in resolving the phylogenetic relationships within the R. microplus complex than 12S rRNA or the nuclear marker ITS2. We suggest that future molecular studies of the R. microplus complex should focus on cox1, supplemented by 16S rRNA, and develop nuclear markers alternative to ITS2 to complement the mitochondrial data.

Phylogenetic analysis of ticks (Acari: Ixodida) using mitochondrial genomes and nuclear rRNA genes indicates that the genus Amblyomma is polyphyletic.

Our understanding of the phylogenetic relationships among tick lineages has been limited by the lack of resolution provided by the most commonly used phylogenetic markers. Mitochondrial genomes are increasingly used to address controversial phylogenetic relationships. To date, the complete mitochondrial genomes of eleven tick species have been sequenced; however, only three of these species are metastriate ticks, the most speciose lineage of ticks. In this study, we present the nucleotide sequences of the complete mitochondrial genomes of five more species of metastriate ticks: Amblyomma elaphense, Amblyomma fimbriatum, Amblyomma sphenodonti, Bothriocroton concolor and Bothriocroton undatum. We use complete mitochondrial genome sequences to address the phylogenetic placement of two morphologically 'primitive' species -Am. elaphense and Am. sphenodonti - with respect to the genus Amblyomma. Our analysis of these five mitochondrial genomes with the other eleven tick mitochondrial genomes, as well as analysis of nuclear rRNA genes, provides strong evidence that the genus Amblyomma is polyphyletic with the inclusion of Am. sphenodonti and Am. elaphense. A new genus or two new genera may be required to describe Am. sphenodonti and Am. elaphense. It is also possible that these two species are sisters to two established genera, Bothriocroton in the case of Am. sphenodonti, and Haemaphysalis in the case of Am. elaphense. However, other arrangements of these taxa cannot be excluded with the current data. Thus, while Am. sphenodonti and Am. elaphense do not belong in the genus Amblyomma, the phylogenetic placement of these two species cannot be resolved without more data from metastriate ticks, either greater sampling of mitochondrial genomes, or a large data set of nuclear genes.

Two new genera of hard ticks, Robertsicus n. gen. and Archaeocroton n. gen., and the solution to the mystery of Hoogstraal's and Kaufman's "primitive" tick from the Carpathian Mountains.

We establish two new monotypic genera, Robertsicus n. gen. and Archaeocroton n. gen., based on two enigmatic species of Amblyomma. Robertsicus, with the type species R. elaphensis (Price, 1959) n. comb., is proposed for Amblyomma       elaphense, the tick of the Trans-Pecos rat-snake of the Chihuahuan Desert of Mexico and southeastern USA (parts of Arizona, West Texas and New Mexico). Archaeocroton, with the type species Ar. sphenodonti (Dumbleton, 1943) n. comb., is proposed for Amblyomma sphenodonti, the tuatara tick of New Zealand. This is another step in the resolution of the systematic problems concerning the genus Aponomma, a heterogeneous group of eyeless ticks with a predilection for reptiles. By removing R. elaphensis (Price, 1959) and Ar. sphenodonti (Dumbleton, 1943) from the genus Amblyomma we have resolved, for now at least, the polyphyly of the genus Amblyomma. We have also resolved a 50-year old mystery: the identity of Hoogstraal's and Kaufman's "primitive" tick from the Carpathian Mountains that had a "striking resemblance" to Ar. sphenodonti n. comb.; it was an Ar. sphenodonti n. comb. that had travelled to the Carpathian       Mountains from New Zealand on a captive tuatara.

Molecular phylogeny of soft ticks (Ixodida: Argasidae) inferred from mitochondrial genome and nuclear rRNA sequences.

The genus-level classification of soft ticks (Argasidae) is controversial. A previous phylogenetic analysis of morphological and developmental characters found that the genus Ornithodoros was paraphyletic and raised a new genus, Carios, for species previously in the genera Antricola, Argas, Ornithodoros, and Nothoaspis (Klompen and Oliver, 1993). Genetic analyses of soft ticks to date have been limited to 16S rRNA, which is not highly phylogenetically informative for this group. We sequenced the entire mitochondrial genomes of 7 species of soft ticks, and the partial mitochondrial genomes of a further 5 species of soft ticks. We used these sequences to test the genus-level classification of soft ticks. Our analyses strongly support a clade of Neotropical species (mostly bat-associated) within the subfamily Ornithodorinae. This clade, which we call Neotropical Ornithodorinae, has species from 2 genera, Antricola and Nothoaspis, and 2 subgenera, Ornithodoros (Alectorobius) and Ornithodoros (Subparmatus). We also addressed the phylogenetic position of Ornithodoros savignyi, the type species of the genus Ornithodoros. Our analysis strongly supports a clade consisting of Ornithodoros savignyi and 4 other Ornithodoros species: Or. brasiliensis, Or. moubata, Or. porcinus, and Or. rostratus. This clade, Ornithodoros sensu stricto, did not contain the Alectorobius and Subparmatus species, Or. (Alectorobius) fonsecai, Or. (Alectorobius) capensis, and Or. (Subparmatus) marinkellei, which in traditional classification schemes have been placed in the genus Ornithodoros. Our comparison of mitochondrial rRNA, nuclear rRNA, and mitochondrial genome analyses show that only mitochondrial genome sequences have the potential to resolve the controversial phylogenetic relationships within the major soft tick lineages, such as the taxonomic status of Carios sensu Klompen and Oliver (1993).

Phylogenetic analysis of the mitochondrial genomes and nuclear rRNA genes of ticks reveals a deep phylogenetic structure within the genus Haemaphysalis and further elucidates the polyphyly of the genus Amblyomma with respect to Amblyomma sphenodonti and Amblyomma elaphense.

We sequenced the entire mitochondrial genomes of 3 species of metastriate ticks: Haemaphysalis formosensis, H. parva, and Amblyomma cajennense. We also sequenced two thirds (ca. 9500bp) of the mitochondrial genomes of H. humerosa and H. hystricis. We used these 5 mitochondrial genome sequences together with the 13 tick mitochondrial genomes we sequenced previously and the 2 tick mitochondrial genomes sequenced by Black and Roehrdanz (1998), as well as the nuclear rRNA genes from 84 ticks and mites, in phylogenetic analyses. Our analyses reveal deep phylogenetic structure within the genus Haemaphysalis, with at least 2 species, H. parva and H. inermis that are highly divergent from the rest of the genus Haemaphysalis. We identify a region of the 18S rRNA gene which correlates with this division of the genus Haemaphysalis as well as a novel insertion in the mitochondrial genome of H. parva. We reject the hypotheses of Hoogstraal and Aeschlimann (1982) and Barker and Murrell (2004) on the relationships among metastriate genera. Instead, our analysis provides further evidence for the division of the Metastriata into 2 major lineages: (i) Amblyomma s.s. plus Rhipicephalinae (i.e. Rhipicephalus, Hyalomma, Rhipicentor, and Dermacentor); and (ii) Haemaphysalis plus Bothriocroton plus Amblyomma sphenodonti. We also provide further evidence for the polyphyly of the genus Amblyomma with respect to A. sphenodonti and A. elaphense. The most likely position of A. elaphense is sister to the rest of the Metastriata; the most likely position of A. sphenodonti is sister to the genus Bothriocroton. These 2 species do not belong in the genus Amblyomma, and we propose that new genera are required for A. sphenodonti and A. elaphense.

Heteroplasmy in the mitochondrial genomes of human lice and ticks revealed by high throughput sequencing.

The typical mitochondrial (mt) genomes of bilateral animals consist of 37 genes on a single circular chromosome. The mt genomes of the human body louse, Pediculus humanus, and the human head louse, Pediculus capitis, however, are extensively fragmented and contain 20 minichromosomes, with one to three genes on each minichromosome. Heteroplasmy, i.e. nucleotide polymorphisms in the mt genome within individuals, has been shown to be significantly higher in the mt cox1 gene of human lice than in humans and other animals that have the typical mt genomes. To understand whether the extent of heteroplasmy in human lice is associated with mt genome fragmentation, we sequenced the entire coding regions of all of the mt minichromosomes of six human body lice and six human head lice from Ethiopia, China and France with an Illumina HiSeq platform. For comparison, we also sequenced the entire coding regions of the mt genomes of seven species of ticks, which have the typical mitochondrial genome organization of bilateral animals. We found that the level of heteroplasmy varies significantly both among the human lice and among the ticks. The human lice from Ethiopia have significantly higher level of heteroplasmy than those from China and France (Pt<0.05). The tick, Amblyomma cajennense, has significantly higher level of heteroplasmy than other ticks (Pt<0.05). Our results indicate that heteroplasmy level can be substantially variable within a species and among closely related species, and does not appear to be determined by single factors such as genome fragmentation.